FR2879046A1 - Drive circuit control method for e.g. piezostrictive actuator, involves controlling drive circuit delivering periodic current whose period has successive sequence of slow falling, rapid falling, another slow falling and rapid rising phases - Google Patents

Abstract

The method involves controlling a drive circuit that delivers a periodic current to an actuator. The period of the delivered current has successive sequence of slow falling phase (B), a rapid falling phase (C), another slow falling phase (D) and a rapid rising phase (E). The drive circuit has a bridge circuit comprising four branches with two branches connected to a DC source such as battery or analog to digital power converter. An independent claim is also included for a drive circuit of an actuator.

Description

A method of controlling a driving circuit for

  piezostrictive or magnetostrictive actuators.

  The invention relates to a method for controlling a control circuit for piezostrictive or magnetostrictive actuators.

  Piezostrictive or magnetostrictive actuators are used in particular in fuel injectors for vehicle engines.

  Automotive injectors have undergone significant developments in recent years. Developments have been made in particular on gasoline or diesel direct injection, high pressure common rail engines or pump injectors.

  The injectors conventionally use an electric fuel supply pump. In the case of a common rail diesel engine, the pump supplies a channel of a distribution manifold of all the injectors under a substantially constant source pressure, of the order of 1600 bars for example. The channel communicates with pipes closed by a respective injector. The opening of a valve of the injector causes the injection, for example in the combustion chamber in case of direct injection.

  The valve conventionally comprises a needle selectively closing an injection nozzle according to commands applied thereto. The needle is conventionally moved between an injection setpoint position and a shutter setpoint position. The displacement of the needle is usually generated by a magnetostrictive actuator or a piezostrictive actuator.

  Moreover, the needle most often has a conical closure end, coming to rest on a seat of the nozzle to ensure sealing. At the initiation of the injection, the needle leaves the seat, and the fuel is temporarily injected forming a bulb. The instantaneous flow rate of the injector is thus not precisely controlled.

  These various problems generally lead to an incomplete and inhomogeneous vaporization of the fuel during the formation of the mixture in the combustion chamber, and to an imprecise control of the richness of the mixture. The consequences are therefore an alteration of the efficiency of the engine and the formation of a large amount of gaseous pollutants.

  The document FR-A-2 801 346 describes an injection device comprising a valve provided with a shutter needle moved by a piezoelectric actuator. The piezoelectric actuator receives a command with an AC component to generate mechanical oscillations of the needle, with respect to the set opening position. In this way, the formation of very fine droplets is precisely controlled.

  Similarly, the document FR 2 762 648 describes an injection device comprising a piezoelectric actuator. The formation of fine droplets is favored by oscillations of an injection nozzle vibrated by the actuator.

  Document FR 2 846 808 is intended to propose an electronic circuit for driving such piezoelectric actuators. The circuit comprises for example a power supply of the bridge actuator, two branches of the bridge comprising controllable switches such as MOS transistors, the other two branches having diodes.

  The circuit is controlled by a control device so as to generate a current supplying the actuator. The current comprises, in a described example, a period, said period comprising a phase of rapid rise of the current, a rapid descent phase and a slow descent phase.

  The inventors have found that this signal was not very effective, that is to say that the amplitude of the oscillations obtained is not very large compared to the amplitude of the current variations. Indeed, the amplitude of the first harmonic has a value of the order of 1, 3 times the amplitude of rapid rise of the current. It is therefore an objective of the invention to propose a method of controlling such a circuit that is more efficient.

  With this objective, the subject of the invention is a method for controlling a circuit delivering a periodic current supplying an actuator, the circuit being able to exclusively control a phase of rapid rise of the current, a phase of rapid descent and a phase of slow descent. The period includes a successive sequence of a first phase of slow descent, a first phase of rapid descent, a second phase of slow descent and a first phase of rapid rise.

  The inventors have found that with such a circuit control method, the efficiency of the current is much better. Indeed, the amplitude of the first order harmonic, that is to say of the same frequency as the period, is much greater than in the signal of the prior art, as will be seen better by the after.

  In a first embodiment, the sequence forms the complete period.

  In a second embodiment, the sequence is followed by a third phase of slow descent, a second phase of rapid rise, a fourth phase of slow descent and a second phase of rapid descent to form a period complete. This produces a signal that is even closer to a sinusoidal signal, which gives it an even greater efficiency.

  In particular, the end of the slow phases is controlled by a clock signal. The end of the slow descent phases and the duration of the signal period are thus precisely controlled.

  Advantageously, for all the embodiments, the end of the fast phases is controlled by the detection of the passage at predetermined current thresholds.

  More particularly, the end of the first fast descent phase is controlled by the detection of the transition to a first predetermined current threshold, the end of the first rapid rise phase is controlled by the detection of the transition to a second predetermined current threshold greater than the first current threshold.

  In the case of the second embodiment, the end of the second fast rise phase is controlled by the detection of the passage to a third predetermined current threshold greater than the second current threshold, and the end of the second fast down phase is controlled by the detection of the passage at the second current threshold.

  The invention also relates to a circuit implementing the above method.

  For this, the circuit comprises for example a finite state machine whose states control the different phases.

  Such a circuit comprises for example a bridge circuit having a first switch connected between a first and a third terminal and a second switch connected between a second and a fourth terminal, a first diode connected between the first and fourth terminals, and whose cathode is connected to said first terminal, a second diode connected between the second and third terminals, and whose cathode is connected to said third terminal, the actuator being connected between the third and fourth terminals of the bridge circuit.

  The invention will be better understood and other features and advantages will become apparent on reading the description which follows, the description referring to the appended drawings in which: FIG. 1 is a schematic representation of the electronic control circuit; FIG. 2 is a diagram showing a desired movement of the actuator applied to a fuel injector; FIG. 3 represents timing diagrams of different signals according to a first embodiment of the invention; FIG. 4 represents a signal according to a second embodiment of the invention.

  FIG. 1 schematically represents an actuating device 1. This actuating device 1 is provided with a not shown actuator, with an electronic control circuit 4 and with a device for controlling the switches 7.

  The actuator comprises an actuated part and an electrical member for controlling the movements of the actuated part. FIG. 1 shows the electric control member L1 in the form of a dipole.

  The electronic control circuit 4 comprises a bridge circuit 5. This bridge circuit 5 comprises, in a manner known per se, four terminals 51, 52, 53 and 54. A continuous electrical source 6, for example a battery or an alternating power converter -continu, is connected to the first and second terminals 51 and 52 of the bridge 5 and provides a voltage or a continuous intensity. The electrical control unit Li is connected between the third and fourth terminals of the bridge circuit 5. A first switch I1 is connected between the first and third terminals 51 and 53, and a second switch 12 is connected between the second and second terminals. and the fourth terminal 54. The electrical control unit Li may be in the form of an integrated circuit in which are formed Mos-type transistors used as switches I1 and 12. It is also possible to use other types of switches such as IGBT transistors or OP amplifiers. Switching of the switches I 1 and I 2 is controlled by means of a device for controlling the switches 7, via control lines 71 and 72. The bridge circuit furthermore has a first and a second diode D 1 and D2. The first diode D1 is connected between the first and fourth terminals 51 and 54, the cathode of the diode D1 being connected to the first terminal 51. The second diode D2 is connected between the second and third terminals 52 and 53, the cathode of the second diode D2 being connected to the third terminal 53.

  In its application to an automobile injector, it is desired to carry out a control sequence of the actuator as shown in FIG. 2. This diagram shows the position of the end of the actuator, for example a needle of the injector, as a function of time. The needle is thus moved initially from a first setpoint position d0 to a second setpoint position d1, with an amplitude equal to dl-d0. The needle then moves alternately by a distance dalt with respect to the second setpoint position d1. Dalt has an amplitude less than dl-d0. The reciprocal displacement of the distance dalt is generally periodic. The needle can subsequently be returned to the first setpoint position d0 or maintained at the setpoint position d1.

  FIG. 3 represents the timing diagrams of different control signals applied by the control device of the switches 7, signals applied across the control electrical component Li, according to a first embodiment of the invention. The electric control member L1 is then electrically assimilated to an inductor.

  The continuous electrical source 6 is in the example a source of DC voltage applying a potential E. In the example shown, the voltage level applied to the gate of the transistors forming the switches Ii and I2 corresponds to their switching position, as this is illustrated in Figure 3. The control device 7 comprises for example a finite state machine whose states control the control signals of the switches.

  During phase A, between times t0 and t1, switches I1 and 12 are closed (OFF) while the hand is at the set position d0. The diodes D1 and D2 are then blocked, and the current takes the following path between the terminals 51 and 52: 51-53-54-52. These numbers correspond to the references of the crossed terminals successively. The voltage Vli between the terminals 53 and 54 is then substantially equal to E. The electrical control member L1 is then crossed by a current Ili growing rapidly.

  During phase B, between times t1 and t2, switch I1 is open (ON) and switch I2 is closed. The diode D2 is blocked, while the diode D1 is on. The current flowing through the electrical control unit L1 short circuit between the terminals 53, 54 and 52. The inductance then restores the energy stored during the previous phases. The voltage Vli between the terminals 53 and 54 is then substantially equal to -V0, which corresponds to the threshold voltage of the diode D1. The electric control member L1 is then traversed by a current Ili decreasing slowly. Phase B is a first phase of slow descent.

  During phase C, between times t2 and t3, switches I1 and I2 are open, while diodes D1 and D2 become on. The current then follows the next path between terminals 51 and 52: 52-53-54-51. The voltage Vli between the terminals 53 and 54 is then substantially equal to - E, the threshold voltages of the diodes D1 and D2 near.

  The electric control member L1 is then traversed by a current Ili decreasing more rapidly than during the phase tl-t2. Phase C is a first phase of rapid descent.

  During phase D, between times t3 and t4, the switches are controlled in the same way as during phase B. The electric control member L1 is then traversed by a current Ili decreasing slowly. Phase D is a second phase of slow descent.

  During phase E, between t4 and t5, the switches are controlled in the same way as during phase A. The electric control unit L1 is then crossed by a current Ili growing rapidly. Phase E is a first phase of rapid rise.

  The alternations of phases B, C, D and E are repeated several times, periodically, when the needle is close to its setpoint position d1, up to time tn, as shown in FIG. needle is then moved to its setpoint position d0, by opening the switches I1 and I2 for a suitable duration.

  In an application of the actuator to an engine injector, it can be provided that the cycle is repeated at a frequency of several tens of hertz depending on the engine speed. The phases of displacement from the setpoint position d1 are repeated at a frequency several times greater than the frequency of the complete cycle.

  Any suitable device for controlling the switches can be used. In this embodiment, use is made in particular of a control device 7 having a measuring element 8 of the signal applied across the electrical control unit L1. The control device 7 compares this signal with a first threshold S1 and a second threshold S2, to switch the different switches of the electronic circuit. It is expected that at the end of the rapid rise or rapid descent phases, it is detected that the current has reached a predetermined current threshold. The pilot device then switches the switches I1 or I2. For example, the transition from the first phase of rapid descent C to the second phase of slow descent D is done during the detection of the passage of the first current threshold S1. Similarly, the transition from the first phase of rapid rise E to the first phase of slow descent B occurs during the detection of the passage of a second current threshold S2, greater than Si.

  For transitions at the end of the slow descent phases, transitions are preferably used on the edges of a clock signal, for example the rising edges of a clock signal tr shown in FIG. the end time t2 of the first slow descent phase B is determined by a first rising edge of the signal tr.

  Similarly, the end time t4 of the end of the second slow descent phase D is determined by a second rising edge of the signal tr.

  It can be seen that with the signal generated according to this first embodiment, the amplitude of the first harmonic has a value of the order of 2.5 times the difference between S1 and S2, which makes it possible to obtain a displacement amplitude approximately twice that obtained with the signal according to the prior art.

  In a second embodiment, as shown in the timing diagram of FIG. 4, the period of the phases B - C - D - E is followed by a third phase of slow descent F between the instants t5 and t6, of a second rapid rise phase G between times t6 and t7, a fourth phase of slow descent H between times t7 and t8 and a second phase of rapid descent J between times t8 and t9. Thus, a first period I is formed of the phases B to J, and is followed by other periods, of which a second period II is represented, composed of the same phases. The first period I is preceded for example by the rapid rise phase A between the instants t0 and t'0, of a phase A 'of slow descent between the instants t'0 and t "O and a phase A" fast descent between times t "O and t1.

  In this embodiment, the transition from the second phase of rapid rise G to the fourth phase of slow descent H is made during the detection at time t7 of the passage of a third predetermined current threshold S3, greater than S2 . Moreover, the transition from the second phase of rapid descent J to the first phase of slow descent B of the following period II occurs during the detection of the passage of the second predetermined current threshold S2 at time t9. As in the first embodiment, the transition at the end of the slow down phases takes place on rising edges of the clock signal tr.

  It can be seen that with the signal generated according to this second embodiment, the amplitude of the first harmonic has a value of the order of 2 times the difference between S1 and S3, which makes it possible to obtain a displacement amplitude of approximately 1 5 times higher than that obtained with the signal according to the prior art.

Claims (10)

  1. A method for controlling a circuit (1) delivering a periodic current supplying an actuator, the circuit being able to control exclusively a phase of rapid rise of the current, a phase of rapid descent and a phase of slow descent, characterized in that that the period includes a successive sequence of a first phase of slow descent (B), a first phase of rapid descent (C), a second phase of slow descent (D) then a first phase of rise fast (E).   The method of claim 1, wherein the sequence forms the complete period.   3. Method according to claim 1, wherein the sequence is followed by a third phase of slow descent (F), a second phase of rapid rise (G), a fourth phase of slow descent (H) and a second rapid descent phase (J) to form a complete period.   4. Control method according to claim 1, wherein the end of the slow phases (B, D, F, H) is controlled by a clock signal.   5. Control method according to claim 1, wherein the end of the fast phases (C, E, G, J) is controlled by the detection of the passage to predetermined current thresholds.   6. A control method according to claim 5, wherein: the end of the first phase of fast descent (C) is controlled by the detection of the passage to a first threshold (Si) of predetermined current.   the end of the first fast rise phase (E) is controlled by the detection of the passage to a second threshold (S2) of predetermined current greater than the first current threshold (S1), 7. A control method according to claims 3 and 6 taken in combination, wherein: - the end of the second fast rise phase (G) is controlled by the detection of the transition to a third predetermined current threshold (S3) greater than second threshold (S2) current, and - the end of the second phase of fast descent (J) is controlled by the detection of the passage to the second threshold (S2) of current.   8. Circuit (1) for controlling an actuator, delivering a periodic current supplying the actuator, the circuit comprising means for exclusively controlling a phase of rapid rise of the current, a phase of rapid descent and a phase of slow descent, characterized in that it comprises means (7) for the period of the delivered current to comprise a successive sequence of a first phase of slow descent (B), of a first phase of rapid descent (C), of a second phase of slow descent (D) then of a first phase of rapid rise (E).   9. Circuit according to claim 8, comprising a finite state machine (7) whose states control the different phases.   10. Circuit according to claim 8, comprising a bridge circuit (5) having a first switch (I1) connected between a first (51) and a third terminal (53) and a second switch (I2) connected between a second (52) ) and a fourth terminal (54); - a first diode (D1) connected between the first (51) and fourth terminal (54), and whose cathode is connected to said first terminal (51); - a second diode (D2) connected between the second (52) and third terminal (53), and whose cathode is connected to said third terminal (53); the actuator (L1) being connected between the third and fourth terminals (53, 54) of the bridge circuit.